Difference between revisions of "Reach for the Stars"

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    | 2020thread    = [https://scioly.org/forums/viewtopic.php?f=285&t=15375 2020]
|B Champion=[[Daniel Wright Junior High School]]
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    | 2020questions = [https://scioly.org/forums/viewtopic.php?f=297&t=16537 2020]
 +
    | 2021thread    = [https://scioly.org/forums/viewtopic.php?f=348&t=18305 2021]
 +
    | testsArchive = true
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    | 1stBName      = Daniel Wright Junior High School
 +
    | 2ndBName      = Solon Middle School
 +
    | 3rdBName      = Winston Churchill Middle School
 +
    | Website      = https://www.soinc.org/reach-stars-b
 
}}
 
}}
 
+
'''Reach for the Stars''' is a [[Division B]] event for the [[2020|2019-2020]] season. This event rotates every two years with [[Solar System]]. It was previously an event during the [[2012|2011-2012]] season, [[2013|2012-2013]] season, [[2016|2015-2016]] season, and [[2017|2016-2017]] season.
'''Reach for the Stars''' is a [[Division B]] event. This event rotates every two years with [[Solar System]]. It was previously an event during the [[2012|2011-2012]] season, [[2013|2012-2013]] season, [[2016|2015-2016]] season, and [[2017|2016-2017]] season.
 
 
 
''For information pertaining to the 2011-2012 rules, see [[Reach for the Stars 2011-2012]].''
 
  
 
==2016-2017 Rules==
 
==2016-2017 Rules==
Line 29: Line 29:
  
 
==Part I==
 
==Part I==
In Part I, students are asked to identify a specified list of stars, constellations, and deep sky objects (DSOs), which may appear on star charts, HR diagrams, planetariums, or other forms of display. Teams must also be knowledgeable about the evolutionary stages of the stars and deep space objects on the list.
+
In Part I, students are asked to identify a [[Reach for the Stars/Stars and DSOs|specified list]] of stars, constellations, and deep sky objects (DSOs), which may appear on star charts, HR diagrams, planetariums, or other forms of display. Teams must also be knowledgeable about the evolutionary stages of the stars and deep sky objects on the list.
 +
 
 +
For lists of this year's and past years' stars and objects, please see the '''[[Reach for the Stars/Stars and DSOs|Star and DSO list]]'''.
 +
 
 
===Star Charts===
 
===Star Charts===
 
During competitions, the star charts given can be from any location on Earth, in any season and at any time of the night. Therefore, it is crucial to be able to recognize stars and constellations in any orientation.
 
During competitions, the star charts given can be from any location on Earth, in any season and at any time of the night. Therefore, it is crucial to be able to recognize stars and constellations in any orientation.
Line 46: Line 49:
 
[[File:SkySydneySummer.png|800px]]
 
[[File:SkySydneySummer.png|800px]]
 
{{SpoilerBoxEnd}}
 
{{SpoilerBoxEnd}}
 
===Stars===
 
 
These are the stars from the 2016-2017 list (not in alphabetical order). With multiple-star systems, the Apparent/Absolute Magnitude is the combined Apparent/Absolute Magnitude of the stars:
 
 
{|class="wikitable"
 
|+2017 Stars
 
! rowspan="2" | Name
 
! rowspan="2" | Images
 
! rowspan="2" | Spectral Type
 
! rowspan="2" | Constellation
 
! colspan="2" | Magnitude
 
! rowspan="2" | Distance
 
! colspan="2" | Coordinates
 
! rowspan="2" | External Links
 
|-
 
! Apparent
 
! Absolute
 
! Right Ascension
 
! Declination
 
|-
 
!rowspan="2" | Altair
 
|rowspan="2" | [[File:Altair1.jpg|200px]]
 
|A7V
 
|Aquila
 
|0.76
 
|2.22
 
|16.73 ly
 
|'''19h 50m 47s'''
 
|'''+08° 52′ 06″ '''
 
|
 
|-
 
| colspan="8" | Altair is a main sequence star in the constellation Aquilla, and makes up one of the stars in the Summer Triangle. This Delta Scuti variable star has a such a high rate of rotation that its equatorial diameter is significantly larger than its polar diameter. Additionally, it exhibits luminosity pulsations between 0.8 and 1.5 hours. A mere 16.7 light years away, this star is visible without the aid of telescopes or other equipment.
 
|-
 
!rowspan="2" | Capella
 
|rowspan="2" | [[File:Capella1.jpg|200px]]
 
|K0III/G1III
 
|Auriga
 
|0.08*
 
| -0.48
 
|42.9ly
 
|'''05h 16m 41s'''
 
|'''+45° 59′ 53″ '''
 
|
 
|-
 
| colspan="8" | [https://en.wikipedia.org/wiki/RS_Canum_Venaticorum_variable| RS CVn Variable Star], a close binary system whose apparent magnitude varies from +0.03 to +0.16.
 
|-
 
!rowspan="2" | Arcturus
 
|rowspan="2" | [[File:Arcturus1.jpg|200px]]
 
|K0III
 
|Boötes
 
| -0.05
 
| -0.30
 
|36.7 ly
 
|'''14h 15m 40s'''
 
|'''+19° 10′ 56″'''
 
|
 
|-
 
| colspan="8" | Red giant star.
 
|-
 
!rowspan="2" | Sirius
 
|rowspan="2" | [[File:Sirius 1.jpg|200px]]
 
|A1Vm/DA2
 
|Canis Major
 
| -1.46
 
|1.42
 
|8.60 ly
 
|'''06h 45m 09s'''
 
|'''−16° 43′ 06″'''
 
|
 
|-
 
| colspan="8" | Brightest star in the night sky. A binary system with Sirius A, a main sequence star, and Sirius B, a white dwarf with Apparent Magnitude 8.44 and Absolute Magnitude 11.18. The name "Sirius" is derived from the Ancient Greek "Seirios", meaning "glowing" or "scorcher".
 
|-
 
!rowspan="2" | Procyon
 
|rowspan="2" | [[File:Procyon1.jpg|200px]]
 
|F5IV-V
 
|Canis Minor
 
|0.34
 
|2.66
 
|11.5 ly
 
|'''07h 39m 18s'''
 
|'''+05° 13′30″'''
 
|
 
|-
 
| colspan="8" | Main sequence star with faint white-dwarf companion.
 
|-
 
!rowspan="2" | Deneb
 
|rowspan="2" | [[File:Deneb1.jpg|200px]]
 
|A2Ia
 
|Cygnus
 
|1.25
 
| -8.38
 
|802 ± 66 pc
 
|'''20h 41m 25.9s'''
 
|'''+45° 16′ 49″ '''
 
|
 
|-
 
| colspan="8" | Blue-white Supergiant.
 
|-
 
!rowspan="2" | Castor
 
|rowspan="4" | [[File:CastorPollux1.jpg|200px]]
 
|
 
|Gemini
 
|
 
|
 
|51 ly
 
|'''07h 34m 36s'''
 
|'''+31° 53′ 18″'''
 
|
 
|-
 
| colspan="8" | Triple Star system.
 
|-
 
!rowspan="2" | Pollux
 
|K0III
 
|Gemini
 
|1.14
 
|1.08
 
|33.8 ly
 
|'''07h 45m 19s'''
 
|'''+28° 01′ 34″ '''
 
|
 
|-
 
| colspan="8" | Giant star.
 
|-
 
!rowspan="2" | Regulus
 
|rowspan="2" | [[File: Regulus.jpg|200px]]
 
|B8 IVn
 
|Leo
 
|1.40
 
| -0.52
 
|79.3 ly
 
|'''10h 08m 22s'''
 
|'''+11° 58′ 02″'''
 
|
 
|-
 
| colspan="8" | Four star system. Values above are only for Regulus A.
 
|-
 
!rowspan="2" | Vega
 
|rowspan="2" | [[File: Vega1.jpg|200px]]
 
|A0Va
 
|Lyra
 
| -0.02-0.07 (0.026)
 
| +0.582
 
|25 ly
 
|'''18h 36m 56s'''
 
|'''+38° 47′ 01″'''
 
|
 
|-
 
| colspan="8" | Suspected Delta Scuti Variable. Northern pole star around 12,000 BC.
 
|-
 
!rowspan="2" | Zeta Ophiuchi
 
|rowspan="2" | [[File: ZetaOph1.jpg|200px]]
 
|O9.5 V
 
|Ophiuchus
 
|2.57
 
| -4.2
 
|366 ly
 
|'''16h 37m 10s'''
 
|'''–10° 34′ 02″'''
 
|
 
|-
 
| colspan="8" | Blue main-sequence star at the start of its life.
 
|-
 
!rowspan="2" | Betelgeuse
 
|rowspan="4" | [[File:Betelgeuse1.jpg|200px]]
 
|M1-M2 Ia-ab
 
|Orion
 
|
 
| -5.85
 
|643 ± 146 ly
 
|'''05h 55m 10s'''
 
|'''+07° 24′ 25″'''
 
|
 
|-
 
| colspan="8" | Semiregular Variable Star.
 
|-
 
!rowspan="2" | Rigel
 
|B8 Ia
 
|Orion
 
|0.13
 
| -7.84
 
|860 ± 80 ly
 
|'''05h 14m 32s'''
 
|'''−08° 12′ 06″'''
 
|
 
|-
 
| colspan="8" | Blue Supergiant with Blue main-sequence companion.
 
|-
 
!rowspan="2" | Algol
 
|rowspan="2" | [[File:Algol1.jpg|200px]]
 
|B8V/K0IV
 
|Perseus
 
|
 
| -0.07
 
|90 ± 3 ly
 
|'''03h 08m 10s'''
 
|'''+40° 57′ 20.3280″'''
 
|
 
|-
 
| colspan="8" | Multiple star system with a pair of eclipsing Variable stars. Counter-intuitively, the lower-mass star is leaving the main-sequence earlier.
 
|-
 
!rowspan="2" | Antares
 
|rowspan="2" | [[File:Antares1.jpg|200px]]
 
|M1.5Iab+B2.5V
 
|Scorpius
 
|0.6-1.6
 
| -5.28
 
|550 ly
 
|'''16h 29m 24.5s'''
 
|'''−26° 25′ 55″'''
 
|
 
|-
 
| colspan="8" | Red Supergiant with Orange main-sequence star companion.
 
|-
 
!rowspan="2" | Aldebaran
 
|rowspan="2" | [[File:Aldebaran1.jpg|200px]]
 
|K5III
 
|Taurus
 
| -0.86
 
| -0.64
 
|65ly
 
|'''04h 35m 55s'''
 
|'''+16° 30′ 33.5″'''
 
|
 
|-
 
| colspan="8" | Orange Giant Star.
 
|-
 
!rowspan="2" | Mizar
 
|rowspan="4" | [[File:MizarAlcor1.jpg|200px]]
 
|A2Vp
 
|Ursa Major
 
|2.27
 
|0.33
 
|86 ± 4 ly
 
|'''13h 23m 55.5s'''
 
|'''+54° 55′ 31″'''
 
|
 
|-
 
| colspan="8" | Visual double with Alcor.
 
|-
 
!rowspan="2" | Alcor
 
|A5Vn
 
|Ursa Major
 
|3.99
 
| 2.00
 
|81.6 ly
 
|'''13h 25m 13.5s'''
 
|'''+54° 59′ 17″'''
 
|
 
|-
 
| colspan="8" | Visual double with Mizar.
 
|-
 
!rowspan="2" | Polaris
 
|rowspan="2" | [[File:Polaris1.jpg|200px]]
 
|F7Ib/F6V
 
|Ursa Minor
 
|1.98
 
| -3.6
 
|323-433 ly
 
|'''02h 31m 49.1s '''
 
|'''+89° 15′ 50.8″'''
 
|
 
|-
 
| colspan="8" | Current Northern pole star; Multiple Star system with Yellow Supergiant orbiting a smaller companion; Cepheid Variable star.
 
|-
 
!rowspan="2" | Spica
 
|rowspan="2" | [[File:Spica1.jpg|200px]]
 
|B1 III-IV/B2 V
 
|Virgo
 
|0.97
 
| -3.55
 
|250±10 ly
 
|'''13h 25m 11.6s'''
 
|'''−11° 09′ 40.8″'''
 
|
 
|-
 
| colspan="8" | Binary star system with a blue giant (beta cepheid variable) and a blue main-sequence star; a spectroscopic binary and rotating ellipsoidal variable; 22400 Kelvin.
 
|-
 
|}
 
 
===Deep Sky Objects===
 
These are the DSOs (Deep Sky Objects) from the 2016-2016 list (not in alphabetical order):
 
 
*'''NGC 7293 (Helix Nebula)''':
 
*'''NGC 3603''':
 
*'''NGC 3372''':
 
*'''Cassiopeia A''':
 
*'''Tycho's SNR''':
 
*'''Cygnus X-1''': Cygnus X-1 is a source of x-rays in the constellation '''Cygnus'''. It is the first widely accepted black hole to be an x-ray source such as itself. It was discovered in 1964 and is located about 6,070 light years from the sun. Cygnus X-1 is a member of a high-mass X-ray binary system. It is about 5 million years old and rotates once every 5.6 days.
 
*'''30 Doradus''': Located in the constellation of '''Dorado''', 30 Doradus is an '''H II region''' also known as the Tarantula Nebula. It is found in the Large Magellanic Cloud (LMC) and has a magnitude of 8.
 
:'''LMC''':
 
:'''Geminga''':
 
:'''NGC 602''':
 
:'''M57 (Ring Nebula)''':
 
:'''Kepler's SNR''':
 
:'''M42 (Orion Nebula)''':
 
:'''Sagittarius A*''':
 
:'''M17''':
 
:'''M8''':
 
:'''M16 (Eagle Nebula)''':
 
:'''M1 (Crab Nebula)''':
 
:'''T Tauri''':
 
:'''SMC''':
 
  
 
===Identification Tips===
 
===Identification Tips===
{{Cleanup|section}}
 
  
The best way to study for the first part of the event is to go outside and look at the sky. If you are not familiar with the constellations this is a great way to learn them. Look up into the sky and use a star chart to find a few constellations and stars. Doing this even a few times a month really pays off.
+
*Go outside and look at the night sky. This is a great way to learn the constellations. Look up into the sky and use a star chart to find constellations and stars. Doing this even a few times a month really pays off.
 
+
*Flash cards with the constellation/star/DSO on the front and its name on the back can really help. Make different flash cards with different information on the front page, such as constellation shape, location on a star chart, or pictures.
Another great way to study for this event to get you ready to go outside is to make flash cards with the constellation on the front and the name and the deep sky objects on the back.
+
*Another tip is to use [https://quizlet.com/ Quizlet], which is great for studying constellations, stars, and DSO's, and may show images that could be seen on a test.
 
+
*When working with star charts or looking at the night sky, many have found it very helpful to relate easy-to-find constellations such as Orion or Ursa Major (Big Dipper) to the constellations around them. This guides you to the constellation via others, rather than having to rely only on the shape. It may be helpful to include a section on the reference sheet about finding constellation you have trouble with on a sky chart. Common "pathways" include:
It is helpful if you can relate easy-to-find constellations such as Orion or Ursa Major (Big Dipper) to the constellations around them. This guides you to the constellation via others, rather than having to rely only on the shape. On your reference sheet, you may want to include a section about how to find the constellations you have trouble with.
+
**Using the handle of the '''Big Dipper''' asterism to find Bootes and Arcturus, and Virgo and Spica, and using the cup to find Ursa Minor and Polaris.
 
+
**Using '''Orion''' to find Taurus, then Auriga, and then Gemini, Perseus, and Andromeda. Cassiopeia is also good for finding Perseus and Andromeda.
Also, in general, the brightest stars (lowest apparent magnitude) in a constellation are Alpha [constellation with slight variance], and second brightest Beta, and so on. After the Greek alphabet has been used up, numbers are used - 1 is dimmer than Omega but brighter than 2. However, there are exceptions - Betelgeuse (Alpha Orionis) usually appears dimmer than Rigel (Beta Orionis), and Castor (Alpha Geminorum) appears to be dimmer than Pollux (Beta Geminorum).
+
**Looking for the '''Winter Triangle''' (Betelgeuse, Sirius, Procyon) and '''Summer Triangle''' (Vega, Altair, Deneb) to find those stars and constellations.
 +
**Using the '''Zodiac''' constellations, which are close to each other around the Ecliptic. This helps with Leo, Virgo, Scorpius, Sagittarius, and Ophiuchus (along with Serpens) especially, but also Gemini and Taurus.
 +
*Sometimes, the test will use a StarLab or planetarium for the identification portion. Put some time in to familiarize yourself with how the skies look on it. This will help reduce confusion on the identifications and reduce the amount of time spent on those questions.
 +
*There is always a chance that a bad star map may be used, so make sure to get accustomed to using less-than-clear maps and images.
 +
*In general, the brightest star (lowest apparent magnitude) in a constellation is denoted Alpha, and second brightest Beta, and so on. After the Greek alphabet has been used up, numbers are used - 1 is dimmer than Omega but brighter than 2. However, there are exceptions: Betelgeuse (Alpha Orionis) usually appears dimmer than Rigel (Beta Orionis), and Castor (Alpha Geminorum) appears to be dimmer than Pollux (Beta Geminorum).
 +
*While identification is not the only part of this event, it is a good way to begin preparing. For the rest of the event, see Part II. A good resource is Astronomy Today.
  
 
==Part II==
 
==Part II==
{{Cleanup|section}}
+
In Part II, students are asked to complete tasks relating to a topics in Astronomy. Students should know about the general characteristics of stars, galaxies, star clusters, etc. Furthermore, students should be able to find a star's spectral class, surface temperature, and evolutionary stage (protostar, main sequence, giant, supergiant, white dwarf) given its position on the Hertzsprung-Russell diagram, or place the star on the diagram given these information. Finally, students should be familiar with basic Astrophysics knowledge such as Luminosity scales and relationships, temperature relationships, flux, and distance measures. For a more in-depth study of astrophysics, please see the [[Astronomy]] page, but Reach for the Stars is unlikely to reach the level of complexity of the C Division event.
 
 
In Part II, students are asked to complete tasks relating to a set of particular topics. Teams must know about the general characteristics of stars, galaxies, star clusters, etc, and be able to figure out a star's spectral class, surface temperature, and evolutionary stage (i.e. giant, supergiant, main sequence, white dwarf) by reading an H-R diagram.
 
 
 
Teams are often asked to use information which includes the following:
 
 
 
*Hertzsprung-Russell diagrams 
 
*Spectra
 
*Light curves
 
*Kepler's laws
 
*Radiation laws (Wien's and Stefan-Boltzmann)
 
*Period-luminosity relationship
 
*Stellar magnitudes and classification
 
*Parallax
 
*Redshift/blueshift
 
*Slides (PowerPoint)
 
*Photographs
 
*Star charts and animations
 
  
 
===Stellar Evolution===
 
===Stellar Evolution===
 +
''This section gives a brief overview of Stellar Evolution. A more detailed discussion of stellar evolution may be found on the [[Astronomy/Stellar Evolution]] page, and other associated pages.''
 +
[[File:StellarEvolution1.jpg|thumb|450px|Stellar Evolution for stars with different masses.]]
  
====Pictures====
+
====Formation====
Know these pictures, credited from Harvard's Chandrasekhar X-Ray Observatory and Hubble Space Telescope. Teams are frequently tasked with putting pictures like these in order based on the stellar life cycle.
+
Star formation starts in a dense interstellar cloud - a dark dust cloud or a molecular cloud. After some instability or disturbance, the cloud collapses under its own gravity, and form clumps of matter. As the clump contracts further, its density grows, its temperature rises, and the clump becomes a protostar.
  
 +
The protostar contracts further and evolves onto the main sequence following the Hayashi track. It enters main sequence when nuclear fusion begins.
  
'''Cas A''' (Cassiopeia A) - super nova remnant
+
====Main Sequence====
(infrared, optical, radio, and X-ray images)
+
Stars spend the majority of their lives on the main sequence. Heavier stars spend significantly less time on the main sequence because their rate of fusion is much higher. The radiation pressure from fusion balances with gravity, and the star is in hydrostatic equilibrium.
  
[[Image:casa1.jpg]] [[Image:0237_optical.gif]] [[Image:casa3.jpg]] [[Image:casa4.jpg]]   
+
Lower-mass stars fuse Hydrogen into Helium mostly using the proton-proton (p-p) chain. This process starts at around [math]4\cdot10^6[/math] Kelvins.
  
 +
Higher-mass stars fuse Hydrogen into Helium mostly using the CNO Cycle. The CNO cycle uses Carbon, Nitrogen and Oxygen as catalysts, and is dominant in temperatures higher than [math]17\cdot10^6[/math] Kelvins.
 +
====Post-Main Sequence, Low Mass====
 +
When the core of a low-mass star is depleted of Hydrogen, nuclear fusion subsides because Helium fusion occurs at much higher temperature. The core contracts, and the heat generated by the contraction heats up the outer layers, creating a Hydrogen-burning shell. The star also expands and becomes a red giant.
  
'''M1''' (Crab Nebula) - Nebula
+
The core then reaches high enough temperature for helium fusion. For a moment, helium is fused rapidly in a runaway condition known as the helium flash, but then subsides as the star enters the horizontal branch.
(infrared, optical, radio, and X-ray images)
 
   
 
[[Image:Crab1.jpg]] [[Image:crab2.jpg]] [[Image:crab4.jpg]] [[Image:crab3.jpg]]
 
  
'''Crab Pulsar''' - fastest pulsar known (30 pulses per second)
+
When a low-mass star runs out of helium, it does not heat up high enough to fuse Carbon into heavier elements, and fusion stops. The core compresses further into a white dwarf, when electron degeneracy pressure prevents it from compressing further, and the outer shell expands into a planetary nebula, heated up by the white dwarf core. The white dwarf slowly cools and becomes a black dwarf.
+
====Post-Main Sequence, High Mass====
[[Image:CrabPulsar.jpg|none|350px]]
+
When the core of a high-mass star is depleted of Hydrogen, the star expands into a red supergiant. Its luminosity stays roughly the same because the temperature of the outer shell decreases. Helium starts fusing into carbon without a runaway process, so there is no helium flash.
  
'''Orion Trapezium Cluster''' - 4 hot young stars in an open cluster in the Orion Nebula
+
A high-mass star is able to fuse elements up to iron, at which point further fusion ''consumes'' energy instead. The iron core contracts further. The star explodes in a bright core-collapse supernova. Then, either electrons combine with protons and the core is made of neutron degenerate matter - a neutron star - or the core contracts further into a black hole. Neutron stars rotate very rapidly and have very strong magnetic fields. Some neutron stars are called pulsars and magnetars for their additional features.
 
[[Image:OTC.jpg]]
 
 
 
'''M57''' (Ring Nebula) - Planetary Nebula
 
(optical, infrared)
 
 
 
[[Image:m57optical1.jpg]] [[Image:m57infrared.jpg]]
 
  
 
===Spectral Classification===
 
===Spectral Classification===
Line 463: Line 146:
 
The following is the class of each of the stars on the list:
 
The following is the class of each of the stars on the list:
  
Class O- None on the list
+
:'''Class O''': Zeta Ophiuchi
 +
:'''Class B''': Rigel, Spica, Regulus, and Algol
 +
:'''Class A''': Vega, Sirius A, Deneb, Altair, Castor, Mizar, and, Alcor
 +
:'''Class F''': Procyon, and Polaris
 +
:'''Class G''': Capella
 +
:'''Class K''': Arcturus, Aldebaran, and Pollux,
 +
:'''Class M''': Betelgeuse, and Antares
  
Class B- Rigel, Spica, Regulus, and Algol
+
There are also S, N, and Y for brown dwarfs, which are generally not considered stars.
  
Class A- Vega, Sirius A, Deneb, Altair, and Castor
+
====Yerkes Spectral Classification====
 +
The Yerkes Spectral Classification is based on luminosity and temperature. It is also known as luminosity classes. There are seven main luminosity classes:
  
Class F- Procyon, and Polaris
+
:'''Type Ia''': Bright Supergiants
 +
:'''Type Ib''': Normal Supergiants
 +
:'''Type II''': Bright Giant
 +
:'''Type III''': Normal Giant
 +
:'''Type IV''': Sub-Giants
 +
:'''Type V''': Main Sequence
 +
:'''Type VI''': Sub-Dwarf
 +
:'''Type VII''': White Dwarf
  
Class G- The Sun, and Capella
+
There is also Type 0, for hypergiants. However, these are exceedingly rare; examples include VY Canis Majoris, the Pistol Star, and R136a1.
  
Class K- Arcturus, Aldebaran, and Pollux,  
+
===Radiation Laws===
 +
'''''NOTE:''' This and the following section contain some algebra. If you are not yet comfortable with algebra, you can still read these sections for the theoretical concepts.''
  
Class M- Betelgeuse, Wolf 359, and Antares
+
The radiation laws show relationships between stellar temperature, radius, and luminosity. All three laws are regarding black bodies, ideal objects that absorbs all incoming radiation. Stars, with little incoming radiation, are often approximated as black bodies to simplify calculations.
 
 
There are also S, N, and Y for brown dwarfs, which are generally not considered stars.
 
  
====Yerkes Spectral Classification====
+
Both Wien's Law and Stefan's Law are '''proportionality statements''', that a change in one quantity is always accompanied by change in other. These can be turned into equations by introducing a constant known as a ''proportionality constant''. The proportionality statement [math]y\propto x[/math] denotes that if [math]x[/math] changes by a factor [math]k[/math] (here, "k" is just an arbitrary variable), [math]y[/math] also changes by [math]k[/math]. However, it does not mean that the values are equal to each other: a proportionality constant needs to be added.
The Yerkes Spectral Classification is based on luminosity and temperature. It is also known as luminosity classes. There are seven main luminosity classes:
 
  
Type Ia- Bright Supergiants
+
At Division B it is unlikely that one will perform calculations with these laws, but general questions regarding these laws, such as the proportionality, may be asked. For details about calculations with these laws, visit [[Astronomy#Radiation Laws|the Astronomy page]].
  
Type Ib- Normal Supergiants
+
====Wien's Law====
  
Type II- Bright Giant
+
Wien's displacement law states that the wavelength where a black-body emits most of its radiation is inversely proportional to the temperature. In other words, as the temperature of a star increases, the wavelength at which the star emits most of its radiation decreases. As a proportionality statement,
 +
<div align="center">[math]\lambda_{max}\propto\frac1T[/math],</div>
 +
where [math]{\lambda}_{max}[/math] is the wavelength of maximum output of radiation from an object and [math]T[/math] is Temperature. For example, if the temperature of a star is multiplied by 2, the wavelength of maximal radiation would be divided by 2.
  
Type III- Normal Giant
+
In order to use this as a normal equation, a proportional constant needs to be added. In this case, [math]b=2900\mu m\cdot K[/math] known as the Wien's displacement constant, is used. Then, <div align="center">[math]\lambda_{max}=\frac{b}{T},[/math]</div> where [math]\lambda_{max}[/math] is in micrometers and [math]T[/math] is in Kelvin. The equation form of the law is more common in Division C, and is unlikely to appear in this event.
  
Type IV- Sub-Giants
+
====Stefan-Boltzmann's Law====
  
Type V- Main Sequence
+
The Stefan-Boltzmann Law states that the total energy emitted from a black-body per unit surface area is proportional to the fourth power of its temperature. In equations, <div align="center">[math]j^*\propto T^4[/math]</div>
 +
where [math]j^*[/math] is the total energy emitted per unit area and [math]T[/math] is Temperature. For example, if the temperature of a star is multiplied by 2, the total energy emitted per unit surface area would be multiplied by [math]2^4=16[/math].
  
Type VI- Sub-Dwarf
+
The proportional constant for this equation is the Stefan–Boltzmann constant [math]\sigma=5.67\cdot 10^{-8}\mathrm{W/m}^2\mathrm{K}^4[/math].  Therefore, [math]j^*=\sigma T^4[/math], where [math]j^*[/math] is in Watts per square meter, and [math]T[/math] is in Kelvin. Again, the equation form is unlikely to appear.
  
VII- White Dwarf
+
Since all black-bodies we encounter are considered to be spheres, they have surface area [math]A=4\pi R^2[/math], where [math]R[/math] is the radius of the object. The luminosity ([math]L[/math]) of a star, which is the total energy emitted from the star, is the product of [math]j^*[/math] and [math]A[/math]. Therefore, since [math]A\propto R^2[/math] and [math]j^*\propto T^4[/math], we end up with the following relationship:
 +
<div align="center">[math]L\propto R^2 T^4.[/math]</div>
  
There is also Type 0, for hypergiants. However, these are exceedingly rare; examples include VY Canis Majoris, the Pistol Star, and R136a1.
+
Stefan's Law relates three different quantities of a star: its luminosity, temperature and radius. Notice that an increase in temperature will have much more of an effect on luminosity than an increase of the same factor in radius, since temperature is raised to the fourth power.
  
===Astrophysics Background===
+
Putting all of the constants back into the relationship to make it an equation again, [math]L=4\pi {R}^{2}\sigma {T}^{4}[/math], with [math]L[/math] in Watts, [math]R[/math] in meters, and [math]T[/math] in Kelvin. Again, questions requiring the use of this specific equation are beyond the scope of this event.
Recent changes to the rules have included more topics relating to basic astrophysics, including luminosity scales and relationships, temperature relationships, flux, and distance measures. A brief introduction to these topics is provided here. For a more in-depth study of astrophysics, please see the [[Astronomy]] page, but Reach for the Stars is unlikely to reach the level of complexity of the C Division event, so this would be mainly for enrichment purposes.
 
  
====Radiation Laws====
+
====Planck's Law====
The radiation laws show relationships between stellar temperature, radius, and luminosity. Both Wien's Law and Stefan's Law are proportionality statements that can be turned into equations by introducing a proportionality constant.
 
  
At Division B it is unlikely that you will perform calculations with these laws. However, general questions regarding these laws, such as the proportionality, may still be asked.
+
Planck's Law states that a hotter blackbody emits more energy at every frequency than a cooler blackbody. The equation form of the law is complicated, while on a radiance vs. temperature graph the law states that ''the curve for a hotter blackbody never dips below that of a cooler one''.
 +
<div align="center">[[file:PlancksLaw1.png|400px]]</div>
  
'''Wien's Law:''' Wien's displacement law states that the wavelength where a blackbody emits most of its radiation is inversely proportional to the temperature. In equations,
+
===Magnitude and Luminosity Scales===
<div align="center">[math]\lambda_{max}\propto\frac1T,\quad\lambda_{max}=\frac{b}{T}[/math],</div>
+
The luminosity of a celestial object refers to how much radiation (visible light, infrared, x-ray, etc.) it emits per unit time. Luminosity is measured in Joules per second or Watts. The luminosity, of the sun, for example, is [math]L_\odot=3.846\cdot 10^{26}[/math] watts. Magnitude scales are different methods to express luminosity.
  
where [math]{\lambda}_{max} [/math] is the maximum output of radiation from an object, [math]T[/math] is Temperature in Kelvin, and [math]b=2900\mu m\cdot K[/math] is known as Wien's displacement constant.
+
====Apparent Magnitude====
 +
The apparent magnitude, denoted by [math]m[/math], denotes the brightness of a celestial object as seen by an observer on Earth. The brighter an object appears, the lower its apparent magnitude. It is a logarithmic scale, not a linear scale, which means that a small decrease in magnitude results in a much greater increase in luminosity. For example, an object with apparent magnitude 5 less than that another would seems 100 times more luminous. Logarithms are very advanced for Division B, but at the very least, it is important to know that a small change in magnitude represents a much larger change in luminosity.
  
For example, the sun has surface temperature [math]T=5778K[/math], so its radiation peaks at [math]\lambda_{max}=\frac{2.9\cdot 10^{-3} m\cdot K}{5778K}=502nm[/math], a yellow-green color.
+
For example, the sun has apparent magnitude of -26.74, while Deneb has apparent magnitude of 1.2. Because of this, the sun seems [math]100^{(1.2+26.74)/5}\approx 150 \text{ billion}[/math] times brighter than Deneb! Apparent magnitude depends on both the luminosity of the object and its distance from Earth: while Deneb is more luminous than the sun, to an observer on Earth it is dimmer because it is farther away.
  
'''Stefan-Boltzmann's Law:''' The Stefan-Boltzmann Law states that the total energy emitted from a black-body per unit surface area is proportional to the fourth power of its temperature. In equations, <div align="center">[math]j^*\propto T^4,\quad j^*=\sigma T^4,[/math]</div>
+
The system of apparent magnitude originated from Greece, where the brightest stars in the night sky were of first magnitude ([math]m=1[/math]), while the faintest to the naked eye were of sixth magnitude ([math]m=6[/math]). The system was formalized and extended beyond 1 to 6 in 1856 by N. R. Pogson.
where [math]j^*[/math] is the total energy emitted per unit area, [math]T[/math] is Temperature in Kelvin, and [math]\sigma=5.67\cdot 10^{-8}\mathrm{W/m}^2\mathrm{K}^4[/math] is known as the Stefan–Boltzmann constant.
 
  
Since all blackbodies we encounter are spheres, it has surface area [math]A=4\pi R^2[/math], where [math]R[/math] is the radius of the object. Combining these equations, the total luminosity  
+
====Absolute Magnitude====
<div align="center">[math]L=4\pi {R}^{2}\sigma {T}^{4}.[/math]</div>
+
The absolute magnitude, denoted by [math]M[/math], denotes the brightness of a celestial object as seen by an observer 10 parsecs (about 32.6 light years) away from the object. Similarly, an object with absolute magnitude 5 less that of another would be 100 times more luminous. The absolute magnitude is basically another way of expressing the luminosity of the object. Scientists often consider the absolute bolometric magnitude [math]M_b[/math] of an object, meaning that its radiation is being measured across all wavelengths.
  
For example, the sun has radius and temperature [math]R=6.96\cdot 10^8 m, T=5778K[/math]. Plugging these into the equation, its luminosity is [math]3.85\cdot 10^{26}\mathrm{W}[/math], which is close to the experimental value of [math]3.83\cdot 10^{26}\mathrm{W}[/math].
+
For example, the sun has absolute magnitude 4.83, while Deneb has absolute magnitude -8.38. This means Deneb is [math]100^{(4.83+8.38)/5}\approx 192\text{ thousand}[/math] times more luminous than the sun. A typical Type Ia supernova has an absolute magnitude of about -19.3.
 
 
'''Planck's Law:''' Planck's Law states that a hotter blackbody emits more energy at every frequency than a cooler blackbody. The equation form of the law is complicated, but on a radiance vs. temperature graph the curve for a hotter blackbody never dips below that of a cooler one.
 
<div align="center">[[file:PlancksLaw1.png|400px]]</div>
 
 
 
====Magnitude and Luminosity Scales====
 
  
 +
====Inverse Square Law====
 +
The inverse square law says that a certain quantity is inversely proportional to the square of the distance relating to that quantity. In this case, "inversely proportional" means that an increase of one number causes a decrease in the other number. For example, suppose an astronomer measures a star of some intensity ([math]I_1[/math]) at a certain distance ([math]D[/math]) from the source. By the inverse square law, we have the following proportion:
 +
<div align="center">[math]I_1\propto \frac{1}{D^2}[/math].</div>
 +
This law also applies to '''Newton's Law of Gravitation'''. The law states that:
 +
<div align="center">[math]F=\frac{Gm_1 m_2}{r^2}[/math]</div>
 +
where [math]m_1[/math] and [math]m_2[/math] are the masses of two objects, [math] r[/math] is the distance between the two objects, and [math]G[/math] is a special constant called Newton's gravitational constant. Since most objects in space are very far away from each other, the bottom part of the fraction is much larger than the top part of the fraction, so the law can be approximated for most far-apart objects by [math]F\approx\frac{1}{r^2}[/math].
  
 +
The law also applies to the electrostatic force and the intensity of sound wave in a gas.
 
====Distance Modulus====
 
====Distance Modulus====
Distance modulus is a way to relate the absolute and apparent magnitudes of objects with the distance between them. Absolute magnitude is a measure of an object's brightness when viewed from a set distance, and apparent magnitude is the brightness that an observer on Earth would experience. The formula is given as:
+
Distance modulus is a way to relate the absolute and apparent magnitudes of objects with the distance between them. The distance modulus equation is as follows:
<div align="center">[math]m-M = 5\log_{10} (d) - 5 [/math].</div>
+
<div align="center">[math]m-M = 5\log_{10} (d) - 5, [/math]</div>
Here, [math]m[/math] is apparent magnitude and [math]M[/math] is the absolute magnitude, with [math]d[/math] being the distance to the object in parsecs. An alternative way of expressing this is:
+
where [math]m[/math] is apparent magnitude, [math]M[/math] is the absolute magnitude, and [math]d[/math] being the distance to the object in parsecs. This equation uses a logarithm, which will more often than not be outside the scope of the Division B event, but for a brief tutorial on logarithms, [https://www.mathsisfun.com/algebra/logarithms.html please see this link]. A different way of expressing this equation is:
 
<div align="center">[math]d=10^{\frac{m-M+5}{5}}[/math].</div>
 
<div align="center">[math]d=10^{\frac{m-M+5}{5}}[/math].</div>
This makes it very quick and easy to solve for the distance.
+
For example, the Supernova SN 2011fe had peak apparent magnitude of [math]m=+9.9[/math], while its absolute magnitude is about [math]M=-19.3[/math]. Therefore, the supernova is <div align="center">[math]d=10^{\frac{9.9+19.3+5}{5}}\approx 7\text{ Mpc},[/math]</div> away from Earth, close to the experimental value of [math]6.4\pm0.5\text{ Mpc}[/math].
 
 
====Inverse Square Law====
 
  
 +
This relationship can be found by using the laws that were discussed earlier. By the inverse square law, an observer 10 times as far as another from the same object would see the object as being 100 times less bright, and so they would mark it as having an apparent magnitude of 5 more than the other observer. Since absolute magnitude is the "apparent magnitude" of an observer 10 parsecs away, the first distance equation can be found by relating all of these factors. This is helpful to know in case theoretical questions are asked about the distance modulus relationship, but tests are unlikely to ask about the fine details for Reach for the Stars.
  
 
===Galaxies===
 
===Galaxies===
Line 549: Line 248:
 
Spirals are classified by presence of a central bar and how tightly the rings are wound.
 
Spirals are classified by presence of a central bar and how tightly the rings are wound.
  
{|classification="wikitable"
+
{|class="wikitable"
 
!Sa
 
!Sa
 
|tightly wound, no central bar
 
|tightly wound, no central bar
Line 576: Line 275:
 
|}
 
|}
  
The spiral galaxies on the list for 2009 are:  
+
The spiral galaxies on the list for 2020 are:  
 +
*M31 Andromeda Galaxy (in Andromeda)
 +
*M101 Pinwheel Galaxy (in Ursa Major)
 +
*NGC 4676 Mice Galaxies (in Coma Berenices)
 +
*NGC 4038/4039 Antennae Galaxies (in Corvus)
  
- M31 Andromeda Galaxy (in Andromeda)
 
  
- M51 Whirlpool Galaxy (In Canes Venatica)
+
====Lenticular Galaxy====
 +
Lenticular Galaxies are intermediate between spiral and elliptical Galaxies, they contain a large scale disk, but do not have spiral arms. Like Elliptical Galaxies, they contain older Stars and have a low rate of star formation.
  
- Milky Way Galaxy (Barred-Spiral)
+
The Lenticular Galaxies on the list for 2020 are:
 +
*M104 Sombrero Galaxy (in Virgo)
 +
*NGC5128 Centaurus A (in Centaurus)
  
 +
[[File:M84.jpg|thumb|175px|An example of an Elliptical Galaxy:(M84)|right]]
 
====Elliptical Galaxy====
 
====Elliptical Galaxy====
 
 
Elliptical Galaxies appear just like they sound- they are elliptical/ spherical. Elliptical Galaxies contain mostly old Population II stars, and also, they have a very low rate of star formation because there is barely any interstellar matter in elliptical galaxies. There is the least amount of Elliptical Galaxies in the known Universe. Also, they are classified by how spherical they are, with E followed by a number from zero to seven. Zero indicates perfectly spherical; seven indicates the extremely elongated and cigar-shaped.
 
Elliptical Galaxies appear just like they sound- they are elliptical/ spherical. Elliptical Galaxies contain mostly old Population II stars, and also, they have a very low rate of star formation because there is barely any interstellar matter in elliptical galaxies. There is the least amount of Elliptical Galaxies in the known Universe. Also, they are classified by how spherical they are, with E followed by a number from zero to seven. Zero indicates perfectly spherical; seven indicates the extremely elongated and cigar-shaped.
[[File:M84.jpg|thumb|175px|An example of an Elliptical Galaxy:(M84)|right]]
 
The Elliptical Galaxies on the list for 2009 are:
 
 
-M84 (in Virgo)
 
  
Concerning M84, some astronomers believe that it actually may be a Lenticular Galaxy (which is a half-way point between a Spiral galaxy and an Elliptical Galaxy)
+
The Elliptical Galaxies on the list for 2020 are:
 +
*M60 (in Virgo)
 +
*NGC 4555 (in Coma Berenices)
  
 +
[[File:Irregular_galaxy.jpg|thumb|175px|An example of an Irregular Galaxy|right]]
  
 
====Irregular Galaxies====
 
====Irregular Galaxies====
 +
Irregular also appear just how they sound- they are without a definite shape. They are normally formed by Spiral or Elliptical Galaxies that have been deformed by different forces- such as gravity. They contain a lot of interstellar matter. There are distinctions between "normal" irregular galaxies - with no hint of shape - and ''peculiar'' galaxies, that have some hint of form - usually, they were bent out of shape by outside forces or became violently active.
  
Irregular also appear just how they sound- they are without a definite shape. They are normally formed by Spiral or [[File:Irregular_galaxy.jpg|thumb|175px|An example of an Irregular Galaxy|right]] Elliptical Galaxies that have been deformed by different forces- such as gravity. They contain a lot of interstellar matter. There are distinctions between "normal" irregular galaxies - with no hint of shape - and ''peculiar'' galaxies, that have some hint of form - usually, they were bent out of shape by outside forces or became violently active.
+
The Irregular Galaxies on the list for 2020 are:
 
+
*Large Magellanic Cloud (in Dorado and Mensa)
The Irregular Galaxies on the list for 2009 are:
+
*Small Magellanic Cloud (in Tucana)
 
 
-Large Magellanic Cloud (in Dorado and Mensa)
 
 
 
-Small Magellanic Cloud (in Tucana)
 
 
 
==Helpful Tips==
 
{{Cleanup|section}}
 
 
 
Identification certainly is not the most important part of this event, it has sometimes been found to be easiest way to begin studying. For the rest of the event, you must study the things mentioned in the table above (make it a checklist if you want). This task is facilitated by Astronomy Today - I have found all the information I have ever needed, either during a test or after a test, in that book.
 
 
 
Sometimes, the test will use a StarLab or planetarium for the identification portion.  I would advise putting some time in to familiarize yourself with how the skies look on it.
 
 
 
Also, there is always a chance that a bad star map may be used, so make sure to get yourself accustomed to anything that may be thrown at you.
 
 
 
The best way to study for the identification part, is not only maps, but actually going outside and finding constellations and stars in the night sky. Not only is star-gazing fun, but it is one of the best ways to learn the location of the constellations and the stars that are on the list.
 
 
 
Another tip is to use Quizlet (https://quizlet.com/), which is great for studying constellations, stars, and DSO's, and may show images you could see on a test.
 
  
 +
===Photo Gallery===
 +
<gallery>
 +
0237 optical.gif|
 +
Casa3.jpg|
 +
Casa4.jpg|
 +
Crab1.jpg
 +
Crab3.jpg|
 +
CrabPulsar.jpg|
 +
</gallery>
 
==Sample Tests==
 
==Sample Tests==
 
 
:Identification practice: [[Media: Reach for the Stars Practice Test.pdf|Reach for the Stars Test (2009)]]
 
:Identification practice: [[Media: Reach for the Stars Practice Test.pdf|Reach for the Stars Test (2009)]]
 
:[https://docs.google.com/viewer?a=v&pid=sites&srcid=cHMzMzRzY2hvb2wub3JnfHdvbGZzY2llbmNlfGd4Ojc2NmJmZWQzZjQ1ZmYxOWE RFTS Test] and [https://docs.google.com/viewer?a=v&pid=sites&srcid=cHMzMzRzY2hvb2wub3JnfHdvbGZzY2llbmNlfGd4OjM3ZWMwNWQ3NjE3ZDhhZGI Pic Sheet for the test]
 
:[https://docs.google.com/viewer?a=v&pid=sites&srcid=cHMzMzRzY2hvb2wub3JnfHdvbGZzY2llbmNlfGd4Ojc2NmJmZWQzZjQ1ZmYxOWE RFTS Test] and [https://docs.google.com/viewer?a=v&pid=sites&srcid=cHMzMzRzY2hvb2wub3JnfHdvbGZzY2llbmNlfGd4OjM3ZWMwNWQ3NjE3ZDhhZGI Pic Sheet for the test]
 
:Also be sure to check out the [[Test Exchange#Reach for the Stars|Reach for the Stars Test Exchange]].
 
:Also be sure to check out the [[Test Exchange#Reach for the Stars|Reach for the Stars Test Exchange]].
  
==Useful Resources==  
+
==Useful Resources and Links==  
 
+
:[[Media:rfts.pdf|An Example of a Reach For The Stars Study Sheet]]
 +
:[[Media:Reach_for_Stars_Guide_Sheet.pdf|Another Example of a Reach For the Stars Guide Sheet (2007)]]
 
:[http://www.amazon.com/gp/product/0131445960/102-1902117-4264106 Astronomy Today by Eric J. Chaisson]
 
:[http://www.amazon.com/gp/product/0131445960/102-1902117-4264106 Astronomy Today by Eric J. Chaisson]
 
::[http://wps.prenhall.com/esm_chaisson_astronomytoday_5/ Another link]
 
::[http://wps.prenhall.com/esm_chaisson_astronomytoday_5/ Another link]
 
:[http://www.amazon.com/gp/product/0534421202/102-1902117-4264106 Foundations of Astronomy by Michael A. Seeds]  
 
:[http://www.amazon.com/gp/product/0534421202/102-1902117-4264106 Foundations of Astronomy by Michael A. Seeds]  
:[http://www.tufts.edu/as/wright_center/cosmic_evolution/docs/fr_1/fr_1_stel.html]
+
:[http://chandra.harvard.edu/photo/index.html Photo index of the Chandra Observatory (Good for DSOs)]  
:[http://chandra.harvard.edu/photo/index.html]  
+
:[http://oposite.stsci.edu/pubinfo/pictures.html STSCI Office of Public Outreach]
:[http://oposite.stsci.edu/pubinfo/pictures.html]
 
 
:[http://newyorkscioly.org/SOPages/Events/Reach.html New York Coaches Conference]
 
:[http://newyorkscioly.org/SOPages/Events/Reach.html New York Coaches Conference]
 
:[http://antwrp.gsfc.nasa.gov/apod/astropix.html Astronomy Picture of the Day]
 
:[http://antwrp.gsfc.nasa.gov/apod/astropix.html Astronomy Picture of the Day]
:[[Media:rfts.pdf|An Example of a Reach For The Stars Study Sheet]]
 
:[[Media:Reach_for_Stars_Guide_Sheet.pdf|Another Example of a Reach For the Stars Guide Sheet (2007)]]
 
 
:[http://aspire.cosmic-ray.org/labs/star_life/starlife_main.html| Hertzsprung-russell diagram study]
 
:[http://aspire.cosmic-ray.org/labs/star_life/starlife_main.html| Hertzsprung-russell diagram study]
 
:[http://onwardtotheedge.wordpress.com/| Astronomy blog, by scioly.org's own AlphaTauri, syo_astro, and foreverphysics]
 
:[http://onwardtotheedge.wordpress.com/| Astronomy blog, by scioly.org's own AlphaTauri, syo_astro, and foreverphysics]
  
 +
{{Earth and Space Event}}
 +
{{2021Events}}
 
[[Category:Event Pages]]
 
[[Category:Event Pages]]
 
[[Category:Study Event Pages]]
 
[[Category:Study Event Pages]]
[[Category:Needs Work]]
+
[[Category:Earth and Space Science Events]]

Revision as of 01:46, 8 September 2020

Template:EventLinksBox Reach for the Stars is a Division B event for the 2019-2020 season. This event rotates every two years with Solar System. It was previously an event during the 2011-2012 season, 2012-2013 season, 2015-2016 season, and 2016-2017 season.

2016-2017 Rules

Each team is allowed to bring 2 double-sided 8.5" x 11" sheets of notes, and may be asked to bring a clipboard and red filtered flashlight. You are allowed to put anything on this paper, such as text, illustrations, tables, and pictures. Calculators are also allowed unless told otherwise by event supervisors.

Part I

In Part I, students are asked to identify a specified list of stars, constellations, and deep sky objects (DSOs), which may appear on star charts, HR diagrams, planetariums, or other forms of display. Teams must also be knowledgeable about the evolutionary stages of the stars and deep sky objects on the list.

For lists of this year's and past years' stars and objects, please see the Star and DSO list.

Star Charts

During competitions, the star charts given can be from any location on Earth, in any season and at any time of the night. Therefore, it is crucial to be able to recognize stars and constellations in any orientation.

Below are three star charts that together cover all Stars and Deep Sky Objects from the 2017 Reach for the Stars list. Mizar and Alcor are binary systems, while 30 Doradus is in the Large Magellanic Cloud.

NYC, Summer Solstice

SkyNYCSummer.png

NYC, Winter Solstice

SkyNYCWinter.png

Sydney, Summer Solstice

SkySydneySummer.png

Identification Tips

  • Go outside and look at the night sky. This is a great way to learn the constellations. Look up into the sky and use a star chart to find constellations and stars. Doing this even a few times a month really pays off.
  • Flash cards with the constellation/star/DSO on the front and its name on the back can really help. Make different flash cards with different information on the front page, such as constellation shape, location on a star chart, or pictures.
  • Another tip is to use Quizlet, which is great for studying constellations, stars, and DSO's, and may show images that could be seen on a test.
  • When working with star charts or looking at the night sky, many have found it very helpful to relate easy-to-find constellations such as Orion or Ursa Major (Big Dipper) to the constellations around them. This guides you to the constellation via others, rather than having to rely only on the shape. It may be helpful to include a section on the reference sheet about finding constellation you have trouble with on a sky chart. Common "pathways" include:
    • Using the handle of the Big Dipper asterism to find Bootes and Arcturus, and Virgo and Spica, and using the cup to find Ursa Minor and Polaris.
    • Using Orion to find Taurus, then Auriga, and then Gemini, Perseus, and Andromeda. Cassiopeia is also good for finding Perseus and Andromeda.
    • Looking for the Winter Triangle (Betelgeuse, Sirius, Procyon) and Summer Triangle (Vega, Altair, Deneb) to find those stars and constellations.
    • Using the Zodiac constellations, which are close to each other around the Ecliptic. This helps with Leo, Virgo, Scorpius, Sagittarius, and Ophiuchus (along with Serpens) especially, but also Gemini and Taurus.
  • Sometimes, the test will use a StarLab or planetarium for the identification portion. Put some time in to familiarize yourself with how the skies look on it. This will help reduce confusion on the identifications and reduce the amount of time spent on those questions.
  • There is always a chance that a bad star map may be used, so make sure to get accustomed to using less-than-clear maps and images.
  • In general, the brightest star (lowest apparent magnitude) in a constellation is denoted Alpha, and second brightest Beta, and so on. After the Greek alphabet has been used up, numbers are used - 1 is dimmer than Omega but brighter than 2. However, there are exceptions: Betelgeuse (Alpha Orionis) usually appears dimmer than Rigel (Beta Orionis), and Castor (Alpha Geminorum) appears to be dimmer than Pollux (Beta Geminorum).
  • While identification is not the only part of this event, it is a good way to begin preparing. For the rest of the event, see Part II. A good resource is Astronomy Today.

Part II

In Part II, students are asked to complete tasks relating to a topics in Astronomy. Students should know about the general characteristics of stars, galaxies, star clusters, etc. Furthermore, students should be able to find a star's spectral class, surface temperature, and evolutionary stage (protostar, main sequence, giant, supergiant, white dwarf) given its position on the Hertzsprung-Russell diagram, or place the star on the diagram given these information. Finally, students should be familiar with basic Astrophysics knowledge such as Luminosity scales and relationships, temperature relationships, flux, and distance measures. For a more in-depth study of astrophysics, please see the Astronomy page, but Reach for the Stars is unlikely to reach the level of complexity of the C Division event.

Stellar Evolution

This section gives a brief overview of Stellar Evolution. A more detailed discussion of stellar evolution may be found on the Astronomy/Stellar Evolution page, and other associated pages.

Stellar Evolution for stars with different masses.

Formation

Star formation starts in a dense interstellar cloud - a dark dust cloud or a molecular cloud. After some instability or disturbance, the cloud collapses under its own gravity, and form clumps of matter. As the clump contracts further, its density grows, its temperature rises, and the clump becomes a protostar.

The protostar contracts further and evolves onto the main sequence following the Hayashi track. It enters main sequence when nuclear fusion begins.

Main Sequence

Stars spend the majority of their lives on the main sequence. Heavier stars spend significantly less time on the main sequence because their rate of fusion is much higher. The radiation pressure from fusion balances with gravity, and the star is in hydrostatic equilibrium.

Lower-mass stars fuse Hydrogen into Helium mostly using the proton-proton (p-p) chain. This process starts at around [math]4\cdot10^6[/math] Kelvins.

Higher-mass stars fuse Hydrogen into Helium mostly using the CNO Cycle. The CNO cycle uses Carbon, Nitrogen and Oxygen as catalysts, and is dominant in temperatures higher than [math]17\cdot10^6[/math] Kelvins.

Post-Main Sequence, Low Mass

When the core of a low-mass star is depleted of Hydrogen, nuclear fusion subsides because Helium fusion occurs at much higher temperature. The core contracts, and the heat generated by the contraction heats up the outer layers, creating a Hydrogen-burning shell. The star also expands and becomes a red giant.

The core then reaches high enough temperature for helium fusion. For a moment, helium is fused rapidly in a runaway condition known as the helium flash, but then subsides as the star enters the horizontal branch.

When a low-mass star runs out of helium, it does not heat up high enough to fuse Carbon into heavier elements, and fusion stops. The core compresses further into a white dwarf, when electron degeneracy pressure prevents it from compressing further, and the outer shell expands into a planetary nebula, heated up by the white dwarf core. The white dwarf slowly cools and becomes a black dwarf.

Post-Main Sequence, High Mass

When the core of a high-mass star is depleted of Hydrogen, the star expands into a red supergiant. Its luminosity stays roughly the same because the temperature of the outer shell decreases. Helium starts fusing into carbon without a runaway process, so there is no helium flash.

A high-mass star is able to fuse elements up to iron, at which point further fusion consumes energy instead. The iron core contracts further. The star explodes in a bright core-collapse supernova. Then, either electrons combine with protons and the core is made of neutron degenerate matter - a neutron star - or the core contracts further into a black hole. Neutron stars rotate very rapidly and have very strong magnetic fields. Some neutron stars are called pulsars and magnetars for their additional features.

Spectral Classification

Harvard Spectral Classification

There are 7 spectral Classes (O,B,A,F,G,K,M). This order is based on decreasing surface temperature. A Class stars have the strongest Hydrogen lines, while M-Class stars have the weakest hydrogen lines. Each class is then subdivided into 10 subdivisions (0-9).

The following is a table with properties of each of the spectral classes.

Spectral Class Properties
Type Temperature (Kelvin) Color Hydrogen
O 30,000-60,000 Blue Weak
B 10,000-30,000 Blue-White Medium
A 7,500-10,000 White Strong
F 6,000-7,500 White Medium
G 5,000-6,000 Yellow Weak
K 3,500-5,000 Yellow-Orange Very Weak
M 2,000-3,500 Red Very Weak

The following is the class of each of the stars on the list:

Class O: Zeta Ophiuchi
Class B: Rigel, Spica, Regulus, and Algol
Class A: Vega, Sirius A, Deneb, Altair, Castor, Mizar, and, Alcor
Class F: Procyon, and Polaris
Class G: Capella
Class K: Arcturus, Aldebaran, and Pollux,
Class M: Betelgeuse, and Antares

There are also S, N, and Y for brown dwarfs, which are generally not considered stars.

Yerkes Spectral Classification

The Yerkes Spectral Classification is based on luminosity and temperature. It is also known as luminosity classes. There are seven main luminosity classes:

Type Ia: Bright Supergiants
Type Ib: Normal Supergiants
Type II: Bright Giant
Type III: Normal Giant
Type IV: Sub-Giants
Type V: Main Sequence
Type VI: Sub-Dwarf
Type VII: White Dwarf

There is also Type 0, for hypergiants. However, these are exceedingly rare; examples include VY Canis Majoris, the Pistol Star, and R136a1.

Radiation Laws

NOTE: This and the following section contain some algebra. If you are not yet comfortable with algebra, you can still read these sections for the theoretical concepts.

The radiation laws show relationships between stellar temperature, radius, and luminosity. All three laws are regarding black bodies, ideal objects that absorbs all incoming radiation. Stars, with little incoming radiation, are often approximated as black bodies to simplify calculations.

Both Wien's Law and Stefan's Law are proportionality statements, that a change in one quantity is always accompanied by change in other. These can be turned into equations by introducing a constant known as a proportionality constant. The proportionality statement [math]y\propto x[/math] denotes that if [math]x[/math] changes by a factor [math]k[/math] (here, "k" is just an arbitrary variable), [math]y[/math] also changes by [math]k[/math]. However, it does not mean that the values are equal to each other: a proportionality constant needs to be added.

At Division B it is unlikely that one will perform calculations with these laws, but general questions regarding these laws, such as the proportionality, may be asked. For details about calculations with these laws, visit the Astronomy page.

Wien's Law

Wien's displacement law states that the wavelength where a black-body emits most of its radiation is inversely proportional to the temperature. In other words, as the temperature of a star increases, the wavelength at which the star emits most of its radiation decreases. As a proportionality statement,

[math]\lambda_{max}\propto\frac1T[/math],

where [math]{\lambda}_{max}[/math] is the wavelength of maximum output of radiation from an object and [math]T[/math] is Temperature. For example, if the temperature of a star is multiplied by 2, the wavelength of maximal radiation would be divided by 2.

In order to use this as a normal equation, a proportional constant needs to be added. In this case, [math]b=2900\mu m\cdot K[/math] known as the Wien's displacement constant, is used. Then,

[math]\lambda_{max}=\frac{b}{T},[/math]

where [math]\lambda_{max}[/math] is in micrometers and [math]T[/math] is in Kelvin. The equation form of the law is more common in Division C, and is unlikely to appear in this event.

Stefan-Boltzmann's Law

The Stefan-Boltzmann Law states that the total energy emitted from a black-body per unit surface area is proportional to the fourth power of its temperature. In equations,

[math]j^*\propto T^4[/math]

where [math]j^*[/math] is the total energy emitted per unit area and [math]T[/math] is Temperature. For example, if the temperature of a star is multiplied by 2, the total energy emitted per unit surface area would be multiplied by [math]2^4=16[/math].

The proportional constant for this equation is the Stefan–Boltzmann constant [math]\sigma=5.67\cdot 10^{-8}\mathrm{W/m}^2\mathrm{K}^4[/math]. Therefore, [math]j^*=\sigma T^4[/math], where [math]j^*[/math] is in Watts per square meter, and [math]T[/math] is in Kelvin. Again, the equation form is unlikely to appear.

Since all black-bodies we encounter are considered to be spheres, they have surface area [math]A=4\pi R^2[/math], where [math]R[/math] is the radius of the object. The luminosity ([math]L[/math]) of a star, which is the total energy emitted from the star, is the product of [math]j^*[/math] and [math]A[/math]. Therefore, since [math]A\propto R^2[/math] and [math]j^*\propto T^4[/math], we end up with the following relationship:

[math]L\propto R^2 T^4.[/math]

Stefan's Law relates three different quantities of a star: its luminosity, temperature and radius. Notice that an increase in temperature will have much more of an effect on luminosity than an increase of the same factor in radius, since temperature is raised to the fourth power.

Putting all of the constants back into the relationship to make it an equation again, [math]L=4\pi {R}^{2}\sigma {T}^{4}[/math], with [math]L[/math] in Watts, [math]R[/math] in meters, and [math]T[/math] in Kelvin. Again, questions requiring the use of this specific equation are beyond the scope of this event.

Planck's Law

Planck's Law states that a hotter blackbody emits more energy at every frequency than a cooler blackbody. The equation form of the law is complicated, while on a radiance vs. temperature graph the law states that the curve for a hotter blackbody never dips below that of a cooler one.

PlancksLaw1.png

Magnitude and Luminosity Scales

The luminosity of a celestial object refers to how much radiation (visible light, infrared, x-ray, etc.) it emits per unit time. Luminosity is measured in Joules per second or Watts. The luminosity, of the sun, for example, is [math]L_\odot=3.846\cdot 10^{26}[/math] watts. Magnitude scales are different methods to express luminosity.

Apparent Magnitude

The apparent magnitude, denoted by [math]m[/math], denotes the brightness of a celestial object as seen by an observer on Earth. The brighter an object appears, the lower its apparent magnitude. It is a logarithmic scale, not a linear scale, which means that a small decrease in magnitude results in a much greater increase in luminosity. For example, an object with apparent magnitude 5 less than that another would seems 100 times more luminous. Logarithms are very advanced for Division B, but at the very least, it is important to know that a small change in magnitude represents a much larger change in luminosity.

For example, the sun has apparent magnitude of -26.74, while Deneb has apparent magnitude of 1.2. Because of this, the sun seems [math]100^{(1.2+26.74)/5}\approx 150 \text{ billion}[/math] times brighter than Deneb! Apparent magnitude depends on both the luminosity of the object and its distance from Earth: while Deneb is more luminous than the sun, to an observer on Earth it is dimmer because it is farther away.

The system of apparent magnitude originated from Greece, where the brightest stars in the night sky were of first magnitude ([math]m=1[/math]), while the faintest to the naked eye were of sixth magnitude ([math]m=6[/math]). The system was formalized and extended beyond 1 to 6 in 1856 by N. R. Pogson.

Absolute Magnitude

The absolute magnitude, denoted by [math]M[/math], denotes the brightness of a celestial object as seen by an observer 10 parsecs (about 32.6 light years) away from the object. Similarly, an object with absolute magnitude 5 less that of another would be 100 times more luminous. The absolute magnitude is basically another way of expressing the luminosity of the object. Scientists often consider the absolute bolometric magnitude [math]M_b[/math] of an object, meaning that its radiation is being measured across all wavelengths.

For example, the sun has absolute magnitude 4.83, while Deneb has absolute magnitude -8.38. This means Deneb is [math]100^{(4.83+8.38)/5}\approx 192\text{ thousand}[/math] times more luminous than the sun. A typical Type Ia supernova has an absolute magnitude of about -19.3.

Inverse Square Law

The inverse square law says that a certain quantity is inversely proportional to the square of the distance relating to that quantity. In this case, "inversely proportional" means that an increase of one number causes a decrease in the other number. For example, suppose an astronomer measures a star of some intensity ([math]I_1[/math]) at a certain distance ([math]D[/math]) from the source. By the inverse square law, we have the following proportion:

[math]I_1\propto \frac{1}{D^2}[/math].

This law also applies to Newton's Law of Gravitation. The law states that:

[math]F=\frac{Gm_1 m_2}{r^2}[/math]

where [math]m_1[/math] and [math]m_2[/math] are the masses of two objects, [math] r[/math] is the distance between the two objects, and [math]G[/math] is a special constant called Newton's gravitational constant. Since most objects in space are very far away from each other, the bottom part of the fraction is much larger than the top part of the fraction, so the law can be approximated for most far-apart objects by [math]F\approx\frac{1}{r^2}[/math].

The law also applies to the electrostatic force and the intensity of sound wave in a gas.

Distance Modulus

Distance modulus is a way to relate the absolute and apparent magnitudes of objects with the distance between them. The distance modulus equation is as follows:

[math]m-M = 5\log_{10} (d) - 5, [/math]

where [math]m[/math] is apparent magnitude, [math]M[/math] is the absolute magnitude, and [math]d[/math] being the distance to the object in parsecs. This equation uses a logarithm, which will more often than not be outside the scope of the Division B event, but for a brief tutorial on logarithms, please see this link. A different way of expressing this equation is:

[math]d=10^{\frac{m-M+5}{5}}[/math].

For example, the Supernova SN 2011fe had peak apparent magnitude of [math]m=+9.9[/math], while its absolute magnitude is about [math]M=-19.3[/math]. Therefore, the supernova is

[math]d=10^{\frac{9.9+19.3+5}{5}}\approx 7\text{ Mpc},[/math]

away from Earth, close to the experimental value of [math]6.4\pm0.5\text{ Mpc}[/math].

This relationship can be found by using the laws that were discussed earlier. By the inverse square law, an observer 10 times as far as another from the same object would see the object as being 100 times less bright, and so they would mark it as having an apparent magnitude of 5 more than the other observer. Since absolute magnitude is the "apparent magnitude" of an observer 10 parsecs away, the first distance equation can be found by relating all of these factors. This is helpful to know in case theoretical questions are asked about the distance modulus relationship, but tests are unlikely to ask about the fine details for Reach for the Stars.

Galaxies

There are three main types of galaxies: Spiral, Elliptical, and Irregular. However, in the 2013 rules, there are no galaxies on the list. Nevertheless, galaxies are an important part of astronomy, so here is a brief background on the types of galaxies.

Spiral Galaxies

An example of a spiral galaxy: (M31 Andromeda Galaxy)

Spiral Galaxies are named so because they have prominent spiral arms and a central "galactic nucleus" or central bulge.

An example of a Barred-Spiral Galaxy: (NGC 1300)

Spiral Galaxies also have a very large rate of star formation in the spiral arms of the galaxy. Also, almost all spiral galaxies have a galactic halo that surrounds the galaxy. These halos contain stray stars and globular clusters. It is also theorized that many spiral galaxies have supermassive black holes at the center of the galaxy. Our own galaxy, The Milky Way, is a spiral galaxy, and is also theorized to have a supermassive black hole at its center, called Sgr A*. There is also a sub-division of spiral galaxies, known as barred-spiral galaxies. Barred-spirals have a central bar, and then have spiral arms shooting off at each end of the bar.

Spirals are classified by presence of a central bar and how tightly the rings are wound.

Sa tightly wound, no central bar
Sb moderately tightly wound, no central bar
Sc loosely wound, no central bar
Sd very loosely wound, no central bar
SBa tightly wound, central bar
SBb moderately tightly wound, central bar
SBc loosely wound, central bar
SBd very loosely wound, central bar

The spiral galaxies on the list for 2020 are:

  • M31 Andromeda Galaxy (in Andromeda)
  • M101 Pinwheel Galaxy (in Ursa Major)
  • NGC 4676 Mice Galaxies (in Coma Berenices)
  • NGC 4038/4039 Antennae Galaxies (in Corvus)


Lenticular Galaxy

Lenticular Galaxies are intermediate between spiral and elliptical Galaxies, they contain a large scale disk, but do not have spiral arms. Like Elliptical Galaxies, they contain older Stars and have a low rate of star formation.

The Lenticular Galaxies on the list for 2020 are:

  • M104 Sombrero Galaxy (in Virgo)
  • NGC5128 Centaurus A (in Centaurus)
File:M84.jpg
An example of an Elliptical Galaxy:(M84)

Elliptical Galaxy

Elliptical Galaxies appear just like they sound- they are elliptical/ spherical. Elliptical Galaxies contain mostly old Population II stars, and also, they have a very low rate of star formation because there is barely any interstellar matter in elliptical galaxies. There is the least amount of Elliptical Galaxies in the known Universe. Also, they are classified by how spherical they are, with E followed by a number from zero to seven. Zero indicates perfectly spherical; seven indicates the extremely elongated and cigar-shaped.

The Elliptical Galaxies on the list for 2020 are:

  • M60 (in Virgo)
  • NGC 4555 (in Coma Berenices)
An example of an Irregular Galaxy

Irregular Galaxies

Irregular also appear just how they sound- they are without a definite shape. They are normally formed by Spiral or Elliptical Galaxies that have been deformed by different forces- such as gravity. They contain a lot of interstellar matter. There are distinctions between "normal" irregular galaxies - with no hint of shape - and peculiar galaxies, that have some hint of form - usually, they were bent out of shape by outside forces or became violently active.

The Irregular Galaxies on the list for 2020 are:

  • Large Magellanic Cloud (in Dorado and Mensa)
  • Small Magellanic Cloud (in Tucana)

Photo Gallery

  • 0237 optical.gif
  • Casa3.jpg
  • Casa4.jpg
  • Crab1.jpg
  • Crab3.jpg
  • CrabPulsar.jpg

Sample Tests

Identification practice: Reach for the Stars Test (2009)
RFTS Test and Pic Sheet for the test
Also be sure to check out the Reach for the Stars Test Exchange.

Useful Resources and Links

An Example of a Reach For The Stars Study Sheet
Another Example of a Reach For the Stars Guide Sheet (2007)
Astronomy Today by Eric J. Chaisson
Another link
Foundations of Astronomy by Michael A. Seeds
Photo index of the Chandra Observatory (Good for DSOs)
STSCI Office of Public Outreach
New York Coaches Conference
Astronomy Picture of the Day
Hertzsprung-russell diagram study
Astronomy blog, by scioly.org's own AlphaTauri, syo_astro, and foreverphysics
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